Friday, July 15, 2016

Whether it's visuals, audio, writing, or design, there's an open source tool out there to help get the job done.
"It's absolutely possible to go from concept to finished, polished products, using free and open source software," said Jason.
In this lightning talk, Opensource.com community moderator Jason van Gumster shares 22 open source tools for creatives:

Sunday, July 10, 2016

Is there a CPU-Z like a freeware/open
source software that detects the central processing unit (CPU) of a
modern personal computer in Linux operating system? How can I get
detailed information about the CPU(s) gathered from the CPUID
instruction, including the exact model of CPU(s) on Linux operating
system?
There are three programs
on Linux operating system that can provide CPUID information and these
tools are useful to find out if specific advanced features such as
virtualization, extended page tables, encryption and more:

lscpu command – Show information on CPU architecture.

x86info command – Show x86 CPU diagnostics.

cpuid command – Dump CPUID information for each CPU. This is the closet tool to CPU-Z app on Linux.

x86info

x86info is a program which displays a range of information about the CPUs present in an x86 system.

cpuid

cpuid
dumps detailed information about the CPU(s) gathered from the CPUID
instruction, and also determines the exact model of CPU(s) from that
information. It dumps all information available from the CPUID
instruction. The exact collection of information available varies
between manufacturers and processors. The following information is
available consistently on all modern CPUs:

Question: I want to back up the file
permissions of the local filesystem, so that if I accidentally mess up
the file permissions, I can restore them to the original state. Is
there an easy way to back up and restore file permissions on Linux?

You may have heard of a tragic mistake of a rookie sysadmin who
accidentally typed "chmod -R 777 /" and wreaked havoc to his/her Linux
system. Sure, there are backup tools (e.g., cp, rsync, etckeeper)
which can back up files along with their file permissions. If you are
using such backup tools, no worries about corrupted file permissions.
But there are cases where you want to temporarily back up file
permissions alone (not files themselves). For example, you want to
prevent the content of some directory from being overwritten, so you
temporarily remove write permission on all the files under the
directory. Or you are in the middle of troubleshooting file permission
issues, so running chmod on files here and there. In these
cases, it will be nice to be able to back up the original file
permissions before the change, so that you can recover the original file
permissions later when needed. In many cases, full file backup is an
overkill when all you really want is to back up file permissions.
On Linux, it is actually straightforward to back up and restore file permissions using access control list (ACL). The ACL defines access permissions on individual files by different owners and groups on a POSIX-compliant filesystem.
Here is how to back up and restore file permissions on Linux using ACL tools.
First of all, make sure that you have ACL tools installed.
On Debian, Ubuntu or Linux Mint:

$ sudo apt-get install acl

On CentOS, Fedora or RHEL:

$ sudo yum install acl

To back up the file permissions of all the files in the current directory (and all its sub directories recursively), run the following command.

$ getfacl -R . > permissions.txt

This command will export ACL information of all the files into a text file named permissions.txt.
For example, the following is a snippet of permissions.txt generated from the directory shown in the screenshot.

I know how to update my system using the yum command.
But, how can I find out that patch has been applied to a package? How
do I search CVE patch number applied to a package under a Red Hat
Enterprise Linux/CentOS/RHEL/Fedora Linux based system?
You need to use the rpm command. Each rpm package stores information
about patches including date, small description and CVE number. You can
use the -q query option to display change information for the package.

Information
is the key to resolving any computer problem, including problems with
or relating to Linux and the hardware on which it runs. There are many
tools available for and included with most distributions even though
they are not all installed by default. These tools can be used to obtain
huge amounts of information.
This article discusses some of the interactive command line interface
(CLI) tools that are provided with or which can be easily installed on
Red Hat related distributions including Red Hat Enterprise Linux,
Fedora, CentOS, and other derivative distributions. Although there are
GUI tools available and they offer good information, the CLI tools
provide all of the same information and they are always usable because
many servers do not have a GUI interface but all Linux systems have a
command line interface.
This article concentrates on the tools that I typically use. If I did
not cover your favorite tool, please forgive me and let us all know
what tools you use and why in the comments section.
My go to tools for problem determination in a Linux environment are
almost always the system monitoring tools. For me, these are top, atop,
htop, and glances.
All of these tools monitor CPU and memory usage, and most of them
list information about running processes at the very least. Some monitor
other aspects of a Linux system as well. All provide near real-time
views of system activity.

Load averages

Before I go on to discuss the monitoring tools, it is important to discuss load averages in more detail.
Load averages are an important criteria for measuring CPU usage, but
what does this really mean when I say that the 1 (or 5 or 10) minute
load average is 4.04, for example? Load average can be considered a
measure of demand for the CPU; it is a number that represents the
average number of instructions waiting for CPU time. So this is a true
measure of CPU performance, unlike the standard "CPU percentage" which
includes I/O wait times during which the CPU is not really working.
For example, a fully utilized single processor system CPU would have a
load average of 1. This means that the CPU is keeping up exactly with
the demand; in other words it has perfect utilization. A load average of
less than one means that the CPU is underutilized and a load average of
greater than 1 means that the CPU is overutilized and that there is
pent-up, unsatisfied demand. For example, a load average of 1.5 in a
single CPU system indicates that one-third of the CPU instructions are
forced to wait to be executed until the one preceding it has completed.
This is also true for multiple processors. If a 4 CPU system has a
load average of 4 then it has perfect utilization. If it has a load
average of 3.24, for example, then three of its processors are fully
utilized and one is utilized at about 76%. In the example above, a 4 CPU
system has a 1 minute load average of 4.04 meaning that there is no
remaining capacity among the 4 CPUs and a few instructions are forced to
wait. A perfectly utilized 4 CPU system would show a load average of
4.00 so that the system in the example is fully loaded but not
overloaded.
The optimum condition for load average is for it to equal the total
number of CPUs in a system. That would mean that every CPU is fully
utilized and yet no instruction must be forced to wait. The longer-term
load averages provide indication of the overall utilization trend.
Linux Journal has an excellent article describing load averages, the theory and the math behind them, and how to interpret them in the December 1, 2006 issue.

Signals

All of the monitors discussed here allow you to send signals
to running processes. Each of these signals has a specific function
though some of them can be defined by the receiving program using signal
handlers.
The separate kill command can also be used to send signals to processes outside of the monitors. The kill -l can be used to list all possible signals that can be sent. Three of these signals can be used to kill a process.

SIGTERM (15): Signal 15, SIGTERM is the default signal sent by top and the other monitors when the k
key is pressed. It may also be the least effective because the program
must have a signal handler built into it. The program's signal handler
must intercept incoming signals and act accordingly. So for scripts,
most of which do not have signal handlers, SIGTERM is ignored. The idea
behind SIGTERM is that by simply telling the program that you want it to
terminate itself, it will take advantage of that and clean up things
like open files and then terminate itself in a controlled and nice
manner.

SIGKILL (9): Signal 9, SIGKILL provides a means of killing
even the most recalcitrant programs, including scripts and other
programs that have no signal handlers. For scripts and other programs
with no signal handler, however, it not only kills the running script
but it also kills the shell session in which the script is running; this
may not be the behavior that you want. If you want to kill a process
and you don't care about being nice, this is the signal you want. This
signal cannot be intercepted by a signal handler in the program code.

SIGINT (2): Signal 2, SIGINT can be used when SIGTERM does
not work and you want the program to die a little more nicely, for
example, without killing the shell session in which it is running.
SIGINT sends an interrupt to the session in which the program is
running. This is equivalent to terminating a running program,
particularly a script, with the Ctrl-C key combination.

To experiment with this, open a terminal session and create a file in
/tmp named cpuHog and make it executable with the permissions
rwxr_xr_x. Add the following content to the file.

Open another terminal session in a different window, position them adjacent to each other so you can watch the results and run top in the new session. Run the cpuHog program with the following command:

/tmp/cpuHog

This program simply counts up by one and prints the current
value of X to STDOUT. And it sucks up CPU cycles. The terminal session
in which cpuHog is running should show a very high CPU usage in top.
Observe the effect this has on system performance in top. CPU usage
should immediately go way up and the load averages should also start to
increase over time. If you want, you can open additional terminal
sessions and start the cpuHog program in them so that you have multiple
instances running.
Determine the PID of the cpuHog program you want to kill. Press the k
key and look at the message under the Swap line at the bottom of the
summary section. Top asks for the PID of the process you want to kill.
Enter that PID and press Enter. Now top asks for the
signal number and displays the default of 15. Try each of the signals
described here and observe the results.

4 open source tools for Linux system monitoring

top

One of the first tools I use when performing problem determination is top. I like it because it has been around since forever and is always available while the other tools may not be installed.
The top program is a very powerful utility that provides a great deal
of information about your running system. This includes data about
memory usage, CPU loads, and a list of running processes including the
amount of CPU time and memory being utilized by each process. Top
displays system information in near real-time, updating (by default)
every three seconds. Fractional seconds are allowed by top, although
very small values can place a significant load the system. It is also
interactive and the data columns to be displayed and the sort column can
be modified.
A sample output from the top program is shown in Figure 1 below. The
output from top is divided into two sections which are called the
"summary" section, which is the top section of the output, and the
"process" section which is the lower portion of the output; I will use
this terminology for top, atop, htop and glances in the interest of
consistency.
The top program has a number of useful interactive commands you can
use to manage the display of data and to manipulate individual
processes. Use the h command to view a brief help page for the various interactive commands. Be sure to press h twice to see both pages of the help. Use the q command to quit.

Summary section

The summary section of the output from top is an overview of the
system status. The first line shows the system uptime and the 1, 5, and
15 minute load averages. In the example below, the load averages are
4.04, 4.17, and 4.06 respectively.
The second line shows the number of processes currently active and the status of each.
The lines containing CPU statistics are shown next. There can be a
single line which combines the statistics for all CPUs present in the
system, as in the example below, or one line for each CPU; in the case
of the computer used for the example, this is a single quad core CPU.
Press the 1 key to toggle between the consolidated
display of CPU usage and the display of the individual CPUs. The data in
these lines is displayed as percentages of the total CPU time
available.
These and the other fields for CPU data are described below.

us: userspace – Applications and other programs running in user space, i.e., not in the kernel.

sy: system calls – Kernel level functions. This does not include CPU time taken by the kernel itself, just the kernel system calls.

ni: nice – Processes that are running at a positive nice level.

id: idle – Idle time, i.e., time not used by any running process.

wa: wait – CPU cycles that are spent waiting for I/O to occur. This is wasted CPU time.

st: steal time – The percentage of CPU cycles that a
virtual CPU waits for a real CPU while the hypervisor is servicing
another virtual processor.

The last two lines in the summary section are memory usage. They show
the physical memory usage including both RAM and swap space.

Figure 1: The top command showing a fully utilized 4-core CPU.

You can use the 1 command to display CPU statistics as a single, global number as shown in Figure 1, above, or by individual CPU. The l command turns load averages on and off. The t and m
commands rotate the process/CPU and memory lines of the summary
section, respectively, through off, text only, and a couple types of bar
graph formats.

Process section

The process section of the output from top is a listing of the
running processes in the system—at least for the number of processes for
which there is room on the terminal display. The default columns
displayed by top are described below. Several other columns are
available and each can usually be added with a single keystroke. Refer
to the top man page for details.

S – The status of the process. This can be R for
running, S for sleeping, and Z for zombie. Less frequently seen statuses
can be T for traced or stopped, and D for uninterruptable sleep.

%CPU – The percentage of CPU cycles, or time used by this process during the last measured time period.

%MEM – The percentage of physical system memory used by the process.

TIME+ – Total CPU time to 100ths of a second consumed by the process since the process was started.

COMMAND – This is the command that was used to launch the process.

Use the Page Up and Page Down keys to scroll through the list of running processes. The d or s
commands are interchangeable and can be used to set the delay interval
between updates. The default is three seconds, but I prefer a one second
interval. Interval granularity can be as low as one-tenth (0.1) of a
second but this will consume more of the CPU cycles you are trying to
measure.
You can use the < and > keys to sequence the sort column to the left or right.
The k command is used to kill a process or the r
command to renice it. You have to know the process ID (PID) of the
process you want to kill or renice and that information is displayed in
the process section of the top display. When killing a process, top asks
first for the PID and then for the signal number to use in killing the
process. Type them in and press the enter key after each. Start with
signal 15, SIGTERM, and if that does not kill the process, use 9,
SIGKILL.

Configuration

If you alter the top display, you can use the W (in uppercase) command to write the changes to the configuration file, ~/.toprc in your home directory.

atop

I also like atop. It is an excellent monitor to use when you need
more details about that type of I/O activity. The default refresh
interval is 10 seconds, but this can be changed using the interval i command to whatever is appropriate for what you are trying to do. atop cannot refresh at sub-second intervals like top can.
Use the h command to display help. Be sure to notice that
there are multiple pages of help and you can use the space bar to scroll
down to see the rest.
One nice feature of atop is that it can save raw performance data to a
file and then play it back later for close inspection. This is handy
for tracking down internmittent problems, especially ones that occur
during times when you cannot directly monitor the system. The atopsar program is used to play back the data in the saved file.

.Figure 2: The atop system monitor provides information about disk and network activity in addition to CPU and process data.

Summary section

atop contains much of the same information as top but also displays
information about network, raw disk, and logical volume activity. Figure
2, above, shows these additional data in the columns at the top of the
display. Note that if you have the horizontal screen real-estate to
support a wider display, additional columns will be displayed.
Conversely, if you have less horizontal width, fewer columns are
displayed. I also like that atop displays the current CPU frequency and
scaling factor—something I have not seen on any other of these
monitors—on the second line in the rightmost two columns in Figure 2.

Process section

The atop process display includes some of the same columns as that
for top, but it also includes disk I/O information and thread count for
each process as well as virtual and real memory growth statistics for
each process. As with the summary section, additional columns will
display if there is sufficient horizontal screen real-estate. For
example, in Figure 2, the RUID (Real User ID) of the process owner is
displayed. Expanding the display will also show the EUID (Effective User
ID) which might be important when programs run SUID (Set User ID).
atop can also provide detailed information about disk, memory,
network, and scheduling information for each process. Just press the d, m, n or s keys respectively to view that data. The g key returns the display to the generic process display.
Sorting can be accomplished easily by using C to sort by CPU usage, M for memory usage, D for disk usage, N for network usage and A
for automatic sorting. Automatic sorting usually sorts processes by the
most busy resource. The network usage can only be sorted if the netatop
kernel module is installed and loaded.
You can use the k key to kill a process but there is no option to renice a process.
By default, network and disk devices for which no activity occurs
during a given time interval are not displayed. This can lead to
mistaken assumptions about the hardware configuration of the host. The f command can be used to force atop to display the idle resources.

Configuration

The atop man page refers to global and user level configuration
files, but none can be found in my own Fedora or CentOS installations.
There is also no command to save a modified configuration and a save
does not take place automatically when the program is terminated. So,
there appears to be now way to make configuration changes permanent.

htop

The htop program is much like top but on steroids. It does
look a lot like top, but it also provides some capabilities that top
does not. Unlike atop, however, it does not provide any disk, network,
or I/O information of any type.

Figure 3: htop has nice bar charts to to indicate resource usage and it can show the process tree.

Summary section

The summary section of htop is displayed in two columns. It is very
flexible and can be configured with several different types of
information in pretty much any order you like. Although the CPU usage
sections of top and atop can be toggled between a combined display and a
display that shows one bar graph for each CPU, htop cannot. So it has a
number of different options for the CPU display, including a single
combined bar, a bar for each CPU, and various combinations in which
specific CPUs can be grouped together into a single bar.
I think this is a cleaner summary display than some of the other
system monitors and it is easier to read. The drawback to this summary
section is that some information is not available in htop that is
available in the other monitors, such as CPU percentages by user, idle,
and system time.
The F2 (Setup) key is used to configure the summary section of
htop. A list of available data displays is shown and you can use
function keys to add them to the left or right column and to move them
up and down within the selected column.

Process section

The process section of htop is very similar to that of top. As with
the other monitors, processes can be sorted any of several factors,
including CPU or memory usage, user, or PID. Note that sorting is not
possible when the tree view is selected.
The F6 key allows you to select the sort column; it displays a
list of the columns available for sorting and you select the column you
want and press the Enter key.
You can use the up and down arrow keys to select a process. To kill a
process, use the up and down arrow keys to select the target process
and press the k key. A list of signals to send the process is
displayed with 15, SIGTERM, selected. You can specify the signal to use,
if different from SIGTERM. You could also use the F7 and F8 keys to renice the selected process.
One command I especially like is F5 which displays the running
processes in a tree format making it easy to determine the parent/child
relationships of running processes.

Configuration

Each user has their own configuration file, ~/.config/htop/htoprc and
changes to the htop configuration are stored there automatically. There
is no global configuration file for htop.

glances

I have just recently learned about glances, which can display more
information about your computer than any of the other monitors I am
currently familiar with. This includes disk and network I/O, thermal
readouts that can display CPU and other hardware temperatures as well as
fan speeds, and disk usage by hardware device and logical volume.
The drawback to having all of this information is that glances uses a
significant amount of CPU resurces itself. On my systems I find that it
can use from about 10% to 18% of CPU cycles. That is a lot so you
should consider that impact when you choose your monitor.

Summary section

The summary section of glances contains most of the same information
as the summary sections of the other monitors. If you have enough
horizontal screen real estate it can show CPU usage with both a bar
graph and a numeric indicator, otherwise it will show only the number.

I like this summary section better than those of the other monitors; I
think it provides the right information in an easily understandable
format. As with atop and htop, you can press the 1 key to toggle
between a display of the individual CPU cores or a global one with all
of the CPU cores as a single average as shown in Figure 4, above.

Process section

The process section displays the standard information about each of
the running processes. Processes can be sorted automatically a, or by CPU c, memory m, name p, user u, I/O rate i, or time t. When sorted automatically processes are first sorted by the most used resource.
Glances also shows warnings and critical alerts at the very bottom of
the screen, including the time and duration of the event. This can be
helpful when attempting to diagnose problems when you cannot stare at
the screen for hours at a time. These alert logs can be toggled on or
off with the l command, warnings can be cleared with the w command while alerts and warnings can all be cleared with x.
It is interesting that glances is the only one of these monitors that
cannot be used to either kill or renice a process. It is intended
strictly as a monitor. You can use the external kill and renice commands to manipulate processes.

Sidebar

Glances has a very nice sidebar that displays information that is not
available in top or htop. Atop does display some of this data, but
glances is the only monitor that displays the sensors data. Sometimes it
is nice to see the temperatures inside your computer. The individual
modules, disk, filesystem, network, and sensors can be toggled on and
off using the d,f, n, and s commands, respectively. The entire sidebar can be toggled using 2.
Docker stats can be displayed with D.

Configuration

Glances does not require a configuration file to work properly. If
you choose to have one, the system-wide instance of the configuration
file would be located in /etc/glances/glances.conf. Individual users can
have a local instance at ~/.config/glances/glances.conf which will
override the global configuration. The primary purpose of these
configuration files is to set thresholds for warnings and critical
alerts. There is no way I can find to make other configuration
changes—such as sidebar modules or the CPU displays—permanent. It
appears that you must reconfigure those items every time you start
glances.
There is a document, /usr/share/doc/glances/glances-doc.html, that
provides a great deal of information about using glances, and it
explicitly states that you can use the configuration file to configure
which modules are displayed. However, neither the information given nor
the examples describe just how to do that.

Conclusion

Be sure to read the man pages for each of these monitors because
there is a large amount of information about configuring and interacting
with them. Also use the h key for help in interactive
mode. This help can provide you with information about selecting and
sorting the columns of data, setting the update interval and much more.
These programs can tell you a great deal when you are looking for the
cause of a problem. They can tell you when a process, and which one, is
sucking up CPU time, whether there is enough free memory, whether
processes are stalled while waiting for I/O such as disk or network
access to complete, and much more.
I strongly recommend that you spend time watching these monitoring
programs while they run on a system that is functioning normally so you
will be able to differentiate those things that may be abnormal while
you are looking for the cause of a problem.
You should also be aware that the act of using these monitoring tools
alters the system's use of resources including memory and CPU time. top
and most of these monitors use perhaps 2% or 3% of a system's CPU time.
glances has much more impact than the others and can use between 10%
and 20% of CPU time. Be sure to consider this when choosing your tools.
I had originally intended to include SAR (System Activity Reporter)
in this article but as this article grew longer it also became clear to
me that SAR is significantly different from these monitoring tools and
deserves to have a separate article. So with that in mind, I plan to
write an article on SAR and the /proc filesystem, and a third article on
how to use all of these tools to locate and resolve problems.

Autofs is a service in Linux like
operating system which automatically mounts the file system and remote
shares when it is accessed. Main advantage of autofs is that you don’t
need to mount file system at all time, file system is only mounted when
it is in demand.

Autofs service reads two files Master map file ( /etc/auto.master ) and a map file like /etc/auto.misc or /etc/auto.xxxx.

In ‘/etc/auto.master’ file we have three different fields :/
In map file (/etc/auto.misc or /etc/auto.xxxx) also we have three different fields:
In this article we will mount the NFS share using autofs. NFS share ‘/db_backup‘ is exported from Fedora NFS Server (192.168.1.21). We are going to mount this nfs share on CentOS 7 & Ubuntu Linux using autofs.

Steps to mount nfs share using Autofs in CentOS 7.

Step:1 Install autofs package.

Install the autofs package using below yum command if it is not installed.

Step:2 Edit the Master map file (/etc/auto.master )

Note : Mount point ‘/dbstuff’‘ must exist on your system. If not then create a directory ‘mkdir /dbstuff‘. NFS Share will automatically umount after 180 seconds or 3 minutes if don’t perform any action on the share.